RU2122281C1 - Generator of signal for turning jamming on - Google Patents

Abstract

FIELD: tracing radar equipment. SUBSTANCE: device generates jamming signal when subjected to pulse sequences or pulse bursts which period is not greater than threshold with total duration of probing pulses not less than given threshold. Device has first resistive voltage divider, first pulse stretcher, integrating RC circuit, first p-n-p transistor, which base is connected to output of first resistor voltage divider, and emitter serves as input of generator of signal for switching jamming station on. Goal of invention is achieved by introduced second p-n-p transistor, second resistive voltage divider, second pulse stretcher, emitter of second p-n-p transistor is connected to output of integrating RC circuit, base is connected to output of second resistive divider, collector to input of second pulse stretcher, which output serves as output of generator of signal for switching jamming station on. EFFECT: possibility to store ON condition for specified period, independent setting of threshold level of burst period, total duration of probing pulses necessary for turning on, as well as time for storing ON state. 3 dwg

Description

 This invention relates to the field of electronic suppression. The device, made in accordance with the proposed technical solution, can be used in automatic radar response stations to generate a signal that switches the jamming station into radiation mode.

At present, the silent mode is usually selected as the initial mode of operation of automatic response radar interference stations - the interference station in this mode only receives and analyzes probing signals of radar means, but does not radiate response interference signals. An interference station enters the radiation mode only if, during the analysis of the probing signals, the incoming signals are identified as belonging to the control radars of the weapon of destruction and the regularity of these signals is confirmed, indicating that the object protected by the interference station is accompanied by the control radar of the weapon of destruction. The regularity of sounding signals is estimated by the duration of their reception and the compliance of the parameters of the sounding signals during the time of their reception with the requirements for the time structure of these signals. Most often, the following system of controlled time parameters is established: the envelope duration of the packet of received pulses τ _p should be at least a boundary value of τ _pg ; the period of the sequence of packs T _p should be no more than the boundary value T _{p pg} ; the total length of time during which sounding signals were received, including those with a burst structure, should be at least the boundary reception time t _sp.gr. In addition, the device that generates the signal to turn on the jamming station according to the analysis of the time structure of the incoming sounding signals should have an on-state memory time τ _memory (i.e., reset the generated signal level of a logical unit no earlier than after a time interval τ _memory after the end of the sounding signals). The selection of probing signals by the duration of the pulse train is a separate, independent type of selection and can sometimes be performed neither in the signal generator of the switching on of the jamming station, but in preliminary selection circuits, for example, in band selectors by the pulse repetition rate. Other types of selection (along the perimeter T _p , parameter t _pr ) and ensuring the memory time τ _pam must be performed in the shaper of the signal to turn on the jamming station. Further, it will be assumed that precisely such tasks are assigned to the shaper of the signal to turn on the interference station: selection by the period T _p , checking the total reception time of the probing signals t _pr and ensuring the memory time τ _memory .
The use of such a set of criteria in the analysis of sounding signals makes it possible to exclude the emission of interfering microwave oscillations during single or irregular sparks in power plants, the appearance of lightning discharges, and the reception of signals emitted by radio-electronic means that are not related to radars for controlling weapons of destruction, for example, early warning radars, etc. e. ultimately, to prevent premature detection of the source of interference and the object on which the interference station is located.

 The probing signals of target tracking radars can be different: pulsed, long-pulse (CI), quasi-continuous with a low repetition rate (KN LFP), quasicontinuous with an average repetition frequency (KN SPP), quasi-continuous with a high repetition rate (KN VChP), continuous. Accordingly, in devices for analyzing the temporal structure of sounding signals used in automatic response jamming stations, there is a set of primary selectors — pulse radiation selectors, continuous radiation selectors, quasi-continuous radiation selectors of various types, etc. After registering each of these signals, its regularity is checked arrivals, i.e., the formation of a signal to turn on a jamming station in each of the selection signals. It can be considered that the formers of the signal for switching on the jamming station are widely used, repeating elements of the station for active jamming, and the reliability of the information received from the shapers of the signal for switching on the jamming station largely determines the correctness of its functioning.

 For definiteness, we will further assume that the signal generator for switching on the jamming station is included in the channel for registering pulsed signals from the radar for controlling weapons of destruction.

 A number of devices are known that process signals by time parameters. One of the known devices is the device described in the article: P. Alekseev. Direction indicator relay with audible indication. - Sat "To help the radio amateur", vol. 66 - M., ed. DOSAAF, 1979, p. 64, Fig. 1. This device will then be considered as a device - an analogue in relation to the proposed.

 The analog device contains a resistive divider from the first and second resistors, a charging resistor, a timing capacitor, an emitter resistor, an n-p-n transistor and a p-n-p transistor. One terminal of the first resistor is connected to one terminal of the charging resistor and to the bus of the positive supply voltage. One terminal of the second resistor is connected to one terminal of the timing capacitor, with the emitter of the p-n-p-resistor and through the signal light with the common bus of the device. The other terminal of the first resistor is connected to the other terminal of the second resistor and to the base of the pnp transistor, the collector of which is connected to the base of the npnn transistor. The emitter of the pnp transistor is connected to one terminal of the emitter resistor, which is connected by its other terminal to the other terminal of the timing capacitor and the other terminal of the charging resistor.

The analog device works as follows. After turning on the power source at the output of the resistive divider, i.e. based on the pnp transistor, a constant voltage is established, the value of which depends on the ratio of the resistances of the first and second resistors and is a fraction of the magnitude of the supply voltage. The voltage on a time-delayed capacitor that has been discharged cannot change abruptly. Therefore, at the first moment after the supply voltage is turned on, the voltage level at the emitter of the pnp transistor is zero, and the pnp transistor is locked, since its base is under voltage greater than the voltage on the emitter. The timing capacitor starts charging from the positive supply voltage through the charging resistor. As long as the voltage across the timing capacitor remains lower than the voltage at the base of the pnp transistor, the latter is locked and its collector current is close to zero. Accordingly, the input current of the base of the npn transistor, which is also in the off state, is also close to zero. When the voltage at the timing capacitor exceeds the output voltage level of the resistive divider by the value of e _about , where e _about is the cutoff voltage of the input characteristic of the transistor, which is of the order of 0.5 V, the pnp transistor will turn on. His collector current appears, which is flowing in for the base circuit of an npn transistor. This incoming current includes an npn transistor, which makes it possible to control subsequent executive circuits. The turn-on delay of the transistor is determined by the charge time of the time-setting capacitor from the initial (zero) voltage to the threshold level set by the resistive divider, consisting of the first and second resistors.

The analog device has significant disadvantages:
a) limited functionality. The analog device is suitable for use only in such nodes where the on-delay is determined by the influence of the supply voltage, and not by any external signal with certain parameters. There is no analog device at all for supplying an external input signal.

 b) Low reliability. This disadvantage is explained by the following. When the p-n-p-transistor is locked, the n-p-n-transistor is also locked, but when the elements used in the analog device are connected, it turns on in the circuit with the “detached” (disconnected) base. This mode, although it causes the n-p-n-transistor to become blocked, is usually prohibited by technical instructions for the use of transistors and is not used in serial equipment.

c) The impossibility of using an analog device for multi-parameter verification of incoming signals - for example, by the period of the bursts T _p and the total time of signal reception t _pr This disadvantage stems from the fact that the analog device has a single timing circuit and a single threshold voltage level.

 Closest to the functions and relationships of the elements to the proposed device is a pulse shaper, described in the description of the invention according to the USSR copyright certificate N 734871 (V.I. Butenko, Yu.N. Erofeev. Relax pulse shaper. USSR copyright certificate N 734871. M. C. H 03 K 5/01. Bulletin of inventions N 18, 1980). This device is further considered as a prototype device in relation to the proposed.

The prototype device is designed to generate a signal of a binary-quantized envelope of a packet of video pulses arriving at the input, if the pulse repetition rate in the packet satisfies the condition F _n ≤ F ≤ F _c , and to save the logical bullet level at the output, if the input repetition frequency pulses in the packet does not satisfy the specified condition.

The prototype device contains:
- resistive divider, consisting of the first and second resistors;
- a pulse expander made on an output npn transistor, a timing capacitor, a timing resistor, a current limiting resistor, a base resistor, a collector resistor and an output npn transistor;
- an integrating RC link, consisting of a capacitor of an integrating RC link, one output of which is the output of the integrating RC link, and a resistor of the integrating RC link.

 The first and second resistors of the resistive divider are connected in series. The connection of the first output of the first resistor and the first output of the second resistor of the resistive divider is the output of the resistive divider. The second output of the first resistor of the resistive divider is connected to the bus of the positive supply voltage. The second output of the second resistor of the resistive divider is connected to a common bus device. The emitter of the output npn transistor of the pulse expander is connected to the common bus of the device; the collector serving as the output of the pulse expander, with the first output of the collector resistor; base - with the first output of the time-setting capacitor, the second output of which is connected to the bus of the negative supply voltage. The second terminal of the collector resistor is connected to the first terminal of the timing resistor and to the bus of the positive supply voltage. The collector of the discharge npn transistor of the pulse expander is connected to the first output of the current-limiting resistor. The base of the discharge npn transistor of the pulse expander is connected to the first output of the base resistor. The emitter of the discharge npn transistor of the pulse expander is connected to the bus of the negative supply voltage. The output of the pulse expander is connected to the cathode of a zener diode, which performs the function of an output voltage comparator.

The prototype device has a number of significant disadvantages:
- insufficiently high functional reliability of the prototype device. This disadvantage is caused by the fact that the output comparator with the potential output in the prototype device is made using a zener diode, which is turned off in the initial state and provides interstage decoupling, and when input signals with a repetition rate belonging to a given range are turned on. However, the zener diode is not an ideal decoupling device. Moreover, the use of the zener diode as an element of interstage galvanic isolation by direct current is not specified by the technical conditions for the zener diode. In isolation mode, the zener diode is used at a reverse voltage close to the voltage on the bus of the negative supply voltage, which does not coincide with any control voltage for the zener diode. The current of the zener diode in the prebreakdown region at a voltage on the zener diode close to the negative supply voltage is not controlled during the manufacture and testing of the zener diode. Therefore, for some samples of zener diodes that satisfy the technical conditions for controlled parameters, the reverse current in the considered region can turn out to be tens of times greater, which is for the bulk of the zener diodes. A large reverse current can lead to the inclusion of the output comparator of the prototype device. It is significant that the reverse current of the zener diode may turn out to be large not under normal conditions, but at elevated ambient temperatures, which further complicates the rejection of such zener diodes. The possibility of an abnormally large reverse current occurring will cause a false response of the prototype device, i.e. causes a false enable signal;
- low adaptability of the device. This drawback is associated with the first noted drawback and is caused by the same reasons. In order to identify a zener diode with an anomalously large reverse current and to ensure one hundred percent use of zener diodes that meet the technical conditions in the equipment (which is the requirements of mass production, since zener diodes that are not suitable for the manufacturer of the equipment for parameters not specified in the technical conditions, there are no complaints and returns to the manufacturer subject), the manufacturing enterprise is forced to carry out additional output control of zener diodes so that zener diodes with an anomalously large t com in the pre region, for example, in voltage stabilizers power sources, and only use zener diodes having a small reverse current when a reverse voltage equal to the voltage on the negative voltage bus for the manufacture of the device-prototype. However, as already noted, the reverse current may turn out to be large not under normal conditions, but at an elevated operating temperature, and such rejection should also be carried out at the maximum operating temperatures of a given temperature range, which further complicates its implementation, since Requires appropriate production equipment and additional monitoring personnel. All this in general complicates the technological cycle of manufacturing the prototype device and makes the production of this device insufficiently technological;
- the impossibility of separate regulation of the memory time and the boundary frequency of a given range F _n . This disadvantage is caused by the fact that in the prototype device both the on-state memory time and the cut-off frequency F _{n are} determined by one parameter: the intrinsic duration of the output pulse of the expander (τ ₀ ), which is part of the prototype device. For example, when the on-state memory time increases due to an increase in the capacitance of the time-setting capacitor of the pulse expander, the selection boundary frequency F _n will inevitably decrease.

 The problem, which is solved when creating the proposed shaper of the signal to turn on the jamming station, is to increase the manufacturability of the device due to the non-selective use of elements that meet the technical conditions, while providing independent adjustment of the cutoff frequency of the selectable frequencies of the input signals, the cutoff value of the total arrival time of the input signals and time on state memory.

 The essence of the proposed technical solution is that in the proposed device, the input circuit is made in the form of a cascade on a locked pnp transistor; a similar cascade is used instead of a zener diode when transmitting a signal from the output of an integrating RC link; as the output stage, a second pulse expander is used, the memory time of which allows you to set the preset time for storing the on state regardless of the value of the cutoff frequency of the selected signals.

 Specifically, technically, the essence of the proposed solution is that in a device containing a first resistive divider connected between a positive supply voltage bus and a common bus and made on the first and second resistors connected in series, the connection point of which is the output of the first resistive divider, the first pulse expander, made on the output npn transistor, connected by a base to the first output of the timing capacitor, the second output of which is connected to the negative bus of the supply voltage, the emitter - with a common bus, the collector, which is the output of the first pulse expander - with the first output of the collector resistor, the second output of which is connected to the first output of the timing resistor and the bus of the positive supply voltage, and on the discharge npn transistor, whose collector connected to the first output of the current-limiting resistor, the emitter is connected to the negative supply voltage bus, and the base is connected to the first output of the base resistor, which integrates the RC link, the first and the findings of the resistor of which are, respectively, the input and output of the integrating RC link, the capacitor of which is connected between the common bus and the second output of the resistor of the integrating RC link, as well as the first pnp transistor, the base of the discharge npn transistor, which is the input of the first pulse expander, connected to the collector of the first pnp transistor, the second output of the base resistor of the first pulse expander is connected to the negative bias bus, the second output of the timing resistor is connected to the collector once the core npn transistor, the second output of the current-limiting resistor is connected to the base of the output npn transistor of the first pulse expander, the output of which is connected to the input of the integrating RC link, the base of the first pnp transistor is connected to the output of the first resistive divider, and the emitter is the input of the station turn-on signal former interference, which also includes a second pnp transistor, a second resistive divider, made and included similarly to the first resistive divider, and a second pulse expander, made similar to the first pulse extender, with the emitter of the second pnp transistor connected to the output of the integrating RC link, the base with the output of the second resistive divider, the collector with the input of the second pulse extender, the output of which is the output of the signal conditioning unit of the jamming station.

The essential features of the proposed device are:
- the presence in its composition of the first and second resistive dividers, the first and second pulse expanders, an integrating RC link, the first and second pnp transistors;
- the implementation of the first resistive divider on the series-connected first and second resistors, the connection point of which is the output of the first resistive divider;
- the implementation of the first pulse expander on the output npn transistor, a timing capacitor, a collector resistor, a timing resistor, a discharge npn transistor, a current limiting resistor, and a base resistor;
- the implementation of the integrating RC link from the resistor of the integrating RC link, the first and second conclusions of which are, respectively, the input and output of the integrating RC link, and the capacitor of the integrating RC link;
- inclusion of the first resistive divider between the bus of the positive supply voltage and the common bus;
- connection of the base of the output npn transistor of the first pulse expander with the first output of the time-setting capacitor, the second output of which is connected to the bus of the negative supply voltage; connecting the emitter of the output npn transistor of the first pulse extender to a common bus, the collector, which is the output of the first pulse extender, to the first output of the collector resistor, the second output of which is connected to the first output of the timing resistor and to the bus of the positive supply voltage; connecting the collector of the npn transistor of the first pulse expander to the first output of the current-limiting resistor, the emitter to the bus of the negative supply voltage, the base to the first output of the base resistor;
- turning on the capacitor of the integrating RC link between the common bus and the second output of the resistor of the integrating RC link;
- connection of the base of the discharge npn transistor, which is the input of the first pulse expander, with the collector of the first pnp transistor;
- connection of the second output of the base resistor of the first pulse expander with a negative bias voltage bus;
-connecting the second output of the timing resistor of the first pulse expander to the collector of the discharge npn transistor;
-connecting the second output of the current-limiting resistor of the first pulse extender to the base of the output npn transistor of the first pulse extender;
- connecting the output of the first pulse expander to the input of the integrating RC link;
- connection of the base of the first pnp transistor with the output of the first resistive divider;
- use of the emitter of the first pnp transistor as an input to the signal shaper to turn on the jamming station;
- the inclusion of a second resistive divider is similar to the first resistive divider;
- the implementation of the second pulse expander is similar to the first pulse expander;
- connection of the emitter of the second pnp transistor with the output of the integrating RC link, the base of the second pnp transistor with the output of the second resistive divider, the collector of the second pnp transistor with the input of the second pulse expander;
- using the output of the second pulse expander as the output of the driver of the signal to turn on the jamming station.

The essential features of the proposed device, common with the prototype device, are:
- the presence in the composition of these devices of the first resistive divider, the first pulse expander, an integrating RC link, the first pnp transistor;
- the implementation of the first resistive divider on the series-connected first and second resistors, the connection point of which is the output of the first resistive divider;
- the implementation of the first pulse expander on the output npn transistor, a timing capacitor, a collector resistor, a timing resistor, a discharge npn transistor, a current limiting resistor, and a base resistor;
- the implementation of the integrating RC link from the resistor of the integrating RC link, the first and second conclusions of which are, respectively, the input and output of the integrating RC link, and the capacitor of the integrating RC link;
- inclusion of the first resistive divider between the bus of the positive supply voltage and the common bus;
- connection of the base of the output npn transistor of the first pulse expander with the first output of the time-setting capacitor, the second output of which is connected to the bus of the negative supply voltage; the connection of the emitter of the output npn transistor of the first pulse expander with a common bus; a collector, which is the output of the first pulse extender, with the first output of the collector resistor, the second output of which is connected to the first output of the timing resistor and to the bus of the positive supply voltage; connecting the collector of the discharge npn transistor of the first pulse expander to the first output of the current-limiting resistor, the emitter to the bus of the negative supply voltage, the base to the first output of the base resistor;
- connecting the capacitor of the integrating RC link between the common bus and the second terminal of the resistor of the integrating RC link;
- connecting the output of the first pulse expander to the input of the integrating RC-link.

The essential features that distinguish the proposed device from the device prototype are:
- connection of the base of the discharge npn transistor, which is the input of the first pulse expander, with the collector of the first pnp transistor;
- connection of the second output of the base resistor of the first pulse expander with a negative bias voltage bus;
- connecting the second output of the current-limiting resistor of the first pulse extender to the base of the output npn transistor of the first pulse extender;
- connecting the base of the first pnp transistor with the output of the first resistive divider;
- use of the emitter of the first pnp transistor as an input to the signal shaper to turn on the jamming station;
- the inclusion of a second pnp transistor, a second resistive divider and a second pulse expander;
- the implementation and inclusion of the second resistive divider is similar to the first resistive divider;
- the implementation of the second pulse expander is similar to the first pulse expander;
- connection of the emitter of the second pnp transistor with the output of the integrating RC link, the base of the second pnp transistor with the output of the second resistive divider, the collector of the second pnp transistor with the input of the second pulse expander;
- using the output of the second pulse expander as the output of the driver of the signal to turn on the jamming station.

 All these differences are significant from the point of view of the task. The implementation of the discharge cascade on the discharge n-p-n-transistor (i.e., the implementation of the discharge cascade as non-regenerative) allows the logic unit signal to be maintained at the output of the device in the case of a long-term presence of the switching signal at the input of the device, which corresponds to the case when the interference station receives a continuous pulse sequence of probe signals. A discharge cascade of a non-regenerative type on a discharge n-p-n-transistor allows you to transmit an output signal of indefinite duration, which is essential when solving the problem.

 The inclusion of the first pnp transistor as an input element for communication with the first pulse expander also contributes to the transmission of a signal of unlimited duration. Unlike the prototype device, where the RC isolation circuit can differentiate an input signal of long duration, the DC coupling circuit on the first pnp transistor does not differentiate the input signal, but transmits it without changing its duration.

The second (output) pulse expander makes it possible to adjust the on-time memory time independent of the boundary values of other parameters of the selected signal. Finally, the use of the first and second pnp transistors in the interstage circuits makes it possible to guarantee the maximum current value of the interstage communication circuit in the absence of an input signal (this current is I _k.o and is a parameter specified by the technical conditions for the transistor, in contrast to the prototype device, where the current of the turned off zener diode in the interstage coupling circuit at a voltage different from the breakdown voltage is uncontrolled and undefined).

The main technical effect of using the proposed solution is to increase the manufacturability of the output of the signal generator for switching on the jamming station: the proposed technical solution is based on the use of only controlled parameters of devices, in particular, the controlled parameter of the pnp transistor - its reverse current I _k.o. In the manufacture of the proposed device does not require preliminary verification and sorting of elements of inter-cascade links.

An additional technical effect consists of:
- the ability to process input signals of any time structure (both in the form of long-existing signals of a logical unit and intermittent signals input during operation of the tracking radar in linear scanning mode);
- in providing independent adjustment of the values of the parameters of the device (T _pgr , t _avegr , τ _memory ).

It is possible to establish the following causal relationship when the marked technical effect is achieved: if you use a locked pnp transistor in the communication circuit of the cascades, which is unlocked only by the input signal, then the current in the communication circuit in the initial state will be determined by the value I _k.o , the maximum value of which is always stipulated by the technical conditions for the pnp transistor, and this will allow not to make any selection or sorting of semiconductor devices used in the device. Further, if the interstage communication circuit is performed on a pnp transistor switched by an input signal without the use of isolation capacitors, and the discharge cascades of the first and second pulse expanders are non-regenerative, with the input circuit on a discharge npn transistor, it becomes possible to process input signals of unlimited duration, those. processing input signals as a discontinuous structure, and in the form of constant levels of a logical unit. Finally, if the output stage of the device is used to make a second pulse expander and the output of the second pulse expander is used as the output of the signal generator for switching on the interference station, it also provides the possibility of increasing the on-time memory time and independently adjusting this to provide an output of an unlimited duration signal time.

 The implementation of the indicated technical solution also leads to a change (in comparison with the prototype device) of the block diagram of the jammer of the jamming signal of the jamming station: the proposed shaper has a symmetrical structure: a circuit consisting of a series-connected resistive divider, a pnp transistor is connected to the input of the integrating RC link pulse extender with a npn discharge transistor; at the same time, the same structure, the circuit is connected to the output of the integrating RC-link.

 Thus, the solution of the problem is achieved through the use of a new structural diagram of the device, the above implementation of its elements and relationships.

Further presentation of the application material will be made using the following illustrations:
FIG. 1. Schematic diagram of the proposed device.

 FIG. 2. Graphs of voltages and currents at characteristic points of the proposed device when the station receives interference probing signals of the target tracking radar operating in the conical scanning mode.

 FIG. 3. Graphs of voltages and currents at characteristic points of the proposed device when the station receives interference probing signals of the target tracking radar operating in the linear scanning mode.

 Consider, using these illustrations, the composition of the elements of the proposed device and the connection of these elements.

The proposed device contains:
- the first resistive divider 1 made of the first resistor 2 and the second resistor 3;
- first pnp transistor 4;
- the first pulse extender 5 having an input 6, an output 7, an input of a positive supply voltage 8, an input of a negative supply voltage 9, an input of a bias voltage 10 and consisting of an output npn transistor 11, a collector resistor 12, a timing resistor 13, a current limiting resistor 14, a base resistor 15, a timing capacitor 16, and a discharge npn transistor 17;
- an integrating RC link 18 having an input 19, an output 20, and consisting of a resistor of an integrating RC link 21 and a capacitor of an integrating RC link 22;
- a second resistive divider 23 made of the first resistor of the second divider 24 and the second resistor of the second divider 25;
- second pnp transistor 26;
- a second pulse extender 27 having an input 28, an output 29, an input of a positive supply voltage 30, an input of a negative supply voltage 31, an input of a bias voltage 32, and consisting of an output npn transistor of a second pulse expander 33, a collector resistor of a second pulse expander 34, a timing resistor the second pulse extender 35, the current-limiting resistor of the second pulse extender 36, the base resistor of the second pulse extender 37, the timing capacitor of the second pulse extender 38, and a discharge npn transistor of a second pulse expander 39;
- input shaper signal inclusion station interference 40;
- the output of the driver of the signal to turn on the jamming station 41;
- bus positive supply voltage 42;
- bus negative supply voltage 43;
- offset voltage bus 44.

 The first resistor 2 and the second resistor 3 of the first resistive divider 1 are connected in series. The connection point of one terminal of the first resistor 2 and one terminal of the second resistor 3 serves as the output of the first resistive divider 1. Another terminal of the first resistor 2 is connected to the bus of the positive supply voltage 42. Another terminal of the second resistor 3 is connected to the common bus of the device. The base of the first pnp transistor 4 is connected to the output of the first resistive divider 1. The emitter of the first pnp transistor 4 serves as the input of the shaper of the switching signal of the jamming station 40. The collector of the first pnp transistor 4 is connected to the input 6 of the first pulse extender 5. The emitter of the output npn transistor 11 the first pulse expander 5 is connected to a common bus device. The collector of the output npn transistor 11 is connected to the first output of the collector resistor 12 and to the output 7 of the first pulse expander. The second terminal of the collector resistor 12 is connected to the first terminal of the base resistor 13 and to the input of the positive supply voltage 8 of the first pulse extender 5. The second terminal of the timing resistor 13 is connected to the first terminal of the current limiting resistor 14 and to the collector of the discharge npn transistor 17, the base of which is connected to the first the output of the base resistor 15 and with the input 6 of the first pulse extender 5. The second output of the current-limiting transistor 14 is connected to the base of the output npn transistor 11 and to the first output time a supply capacitor 16, the second terminal of which is connected to the emitter of the discharge npn transistor 17 and with the input of the negative supply voltage 9 of the first pulse extender 5. The second output of the base resistor 15 is connected to the input of the bias voltage 10 of the first pulse extender 5. The first output of the integrating RC- resistor 21 link 18 serves as the input of the integrating RC link and is connected to the output 7 of the first pulse expander 5. The second output of the resistor 21 of the integrating RC link 18 serves as the output of the integrating RC link and is connected to the first output m of capacitor 22 of the integrating RC link and with the emitter of the second pnp transistor 26. The second output of the capacitor 22 of the integrating RC link 23 is connected to the device common bus. The first 24 and second 25 resistors of the second resistive divider are connected in the same way as the first 2 and second 3 resistors of the first resistive divider 1. The output of the second resistive divider is connected to the base of the second pnp transistor 26. The elements of the second pulse expander 27 are connected as well as the elements of the first expander pulses 5. The input 28 of the second pulse extender 27 is connected to the collector of the second pnp transistor 26. The output 29 of the second pulse extender 27 is connected to the output 41 of the proposed device.

 The input of the positive supply voltage 8 of the first pulse extender 5 and the input of the positive voltage 30 of the second pulse extender 27 are connected to the bus of the positive voltage 42. The input 9 of the negative voltage of the first pulse extender 5 and the input 31 of the negative voltage of the second pulse extender 27 are connected to the negative bus supply voltage 43. Input 10 of the bias voltage of the first pulse extender 5 and input 32 of the bias voltage of the second pulse extender 27 connected to a bias voltage bus 44.

The proposed device operates as follows. After the supply voltage is turned on, the output of the first resistive divider 1 generates a constant positive voltage, which is part of the positive supply voltage acting on the bus of the positive supply voltage 42. The voltage value at the output of the first resistive divider is determined by the voltage division coefficient in the specified divider. Denote the voltage at the output of the first resistive divider 1 as U _about . The logic zero level at the input terminal 40 in the initial state should be less than U _о , the level of the logic unit when the input signal appears, should be large U _о .

In the absence of input pulses, i.e. at a logic zero at the input terminal 40, the first pnp transistor 4 will be locked, since its emitter junction is biased in the opposite direction. The collector current of the locked first pnp transistor 4 is I _k.o. and for silicon transistors it is close to zero. The negative bias voltage applied to the bias voltage bus 44 is in absolute value larger than the negative power voltage available on the negative voltage bus 43. Through the base resistor 15 of the first pulse expander 5, a negative bias voltage is supplied to the base of the discharge npn transistor 17 and biases the emitter junction of this transistor in the opposite direction. The discharge npn transistor 17 is turned off. In the base circuit of the output npn transistor 11 of the first pulse expander 5, a direct (flowing into the base) base current will flow. It flows from the bus 42 of the positive supply voltage through the timing resistor 13 of the first pulse expander 5, the current-limiting resistor 14 (with a low resistance value) and the emitter junction of the output npn transistor 11 to the device common bus. The ratio of the resistances of the collector resistor 12 and the timing resistor 13 of the first pulse expander 5 is chosen so that the direct current flowing into the base of the output npn transistor 11 is sufficient to saturate this transistor. At the output 7 of the first pulse expander 5, a voltage + U _k.n is set equal to the voltage at the collector of the saturated transistor 11, which is a fraction of a volt and corresponds to the level of logical zero at the output of the expander. The same voltage is established at the capacitor 22 of the integrating RC link 18, at the output 20 of the integrating RC link 18 and at the emitter of the second pnp transistor 26. The voltage from the output of the second resistive divider 23 is supplied to the base of the second pnp transistor 26. The output voltage of the second the resistive divider 23 is such that the emitter junction of the second pnp transistor 26 is biased in the opposite direction. The second pnp transistor 23 will be locked, its collector current is close to zero. The base of the npn transistor 39 of the second pulse extender 27 is connected to the bias voltage bus 44 through the base resistor 37 of the second pulse extender. Therefore, the npn transistor 39 of the second pulse extender 27 will be locked. A direct (flowing) current will flow in the base circuit of the output npn transistor 33 of the second pulse expander. It flows from the positive supply terminal 42 through a timing resistor 35 of the second pulse extender, a current limiting resistor 36 of the second pulse extender, and an emitter junction of the output npn transistor 33 of the second pulse extender to the device common bus. The ratio of the resistances of the collector 34 and the timing 35 resistors of the second pulse extender is such that the forward base current saturates the output npn transistor of the second pulse extender. The voltage at the output 29 of the second pulse extender 27 and the output 41 of the signal shaper to turn on the interference station will be + U _k.n - the voltage at the collector of the saturated output npn transistor 33 of the second pulse extender, i.e. matches logical zero.

The input 40 of the proposed device, the signal comes from the registrar of signals of the radar control weapons of destruction - for example, from the registrar of signals of pulsed radar tracking. The shape of the input signal depends on the type of pulse processing in the radar when tracking the target. The signals of radars operating in the conical scanning mode of the beam of the antenna system correspond to a constant voltage with a level of a logical unit at input 40 of the driver of the jamming signal. Some radars accompany the target "on the aisle", working in the linear beam scanning mode. The signal at the input 40 of the proposed device in this case has the form of a binary-quantized envelope of pulse packets, i.e. represents pulses with an amplitude corresponding to the level of a logical unit, a duration equal to the duration of the packet τ _p and a period equal to the period of the packets T _p . We will first assume that the radar that accompanies the protected object operates in a conical scanning mode, and a constant voltage with a logic level is applied to the input 40 of the proposed device. The level of the logical unit exceeds the voltage + U _о supplied to the base of the first pnp transistor 4 from the output of the first resistive divider 1. Therefore, when the input signal drops to the level of the logical unit, the first pnp transistor 4 is turned on, and the collector current of this transistor appears. The collector current of the first pnp transistor 4 serves as the direct (switching) current of the base of the discharge npn transistor 17 of the first pulse expander 5. The discharge npn transistor 17 is turned on, enters the saturation mode. Through the output circuit ("emitter-collector") of a saturated discharge npn transistor 17 and a current limiting resistor 14 having a small resistance value, the negative supply voltage from bus 43 is transmitted to the base of the output npn transistor 11 of the first pulse extender 5 and closes the output npn transistor 11. After locking the specified transistor, the charge of the capacitor 22 of the integrating RC link 18 begins. The capacitor 22 of the integrating RC link is charged from the positive supply voltage acting on the positive bus 42 its voltage via a collector resistor 12 of the first pulse of the expander 5, and a resistor 21, an integrating RC-link 18 (resistor 21, integrating link 18, as compared with the resistance of the collector resistor 12 has a small value). The time constant of the charge circuit of the capacitor 22 of the integrating RC link is determined mainly by the resistance of the collector resistor 12 of the first pulse extender 5 and the capacitance of the capacitor 22 of the integrating RC link. When the voltage at the capacitor 22 of the integrating RC link, and therefore at the output 20 of the integrating RC link 18 exceeds the level + U _о supplied to the base of the second pnp transistor 26 from the output of the second resistive divider 23, the second pnp transistor 26 is turned on and a current begins to flow in the circuit of its collector, which is the direct (switching) current of the base circuit of the discharge npn transistor 39 of the second pulse expander 27. The discharge npn transistor 39 of the second pulse expander turns on and enters saturation mode. Through the output circuit (“collector-emitter”) of the saturated discharge npn transistor 39 of the second pulse extender 27 and the current-limiting resistor 36 of the second pulse extender 27, the negative supply voltage from the negative supply voltage bus 43 is transmitted to the base of the output npn transistor 33 of the second pulse extender 27 and locks this transistor. At the collector of the output npn transistor 33 of the second pulse expander 27, and therefore at the output of the signal shaper to turn on the jamming station 41, a voltage close to the value of the positive supply voltage will be generated. This output voltage level at the collector of the output npn transistor 33 of the second pulse expander 27 corresponds to the level of the logical unit of the output signal.

Thus, after the turn-on delay interval, determined by the charge time of the capacitor of the integrating RC link to the threshold value + U _о , a signal of a logical unit will appear at the output of the device. This output level at the output terminal 41 will exist at all times when a logic unit signal is present at the input terminal 40. The charge time of the capacitor 22 of the integrating RC-link 18 is set equal to the required boundary time of reception of the probing signals t _sp.gr. In this case, the signal at the input, existing for a time greater than t _sp.gr. , will cause the appearance of a logical unit at the output. An input signal that has stopped earlier than the _{expiration of the} time interval t for _example will not create a reaction at the output of the proposed device.

After the input signal stops and the discharge npn transistor 17 of the first pulse expander 5 is turned on, the time-setting capacitor 16 of the first pulse expander 5 is quickly discharged through a current-limiting resistor 14 with a small resistance value and the output circuit (collector-emitter) of a saturated discharge npn transistor 17. After switching on the discharge npn transistor 39 of the second pulse expander 27 time-setting capacitor 38 of the second pulse expander 27 is quickly discharged through a current-limiting resistor 36 of the second expansion erator 27 and pulse output circuit ( "collector-emitter") saturated discharge transistor 39. The current limiting resistor 14 limits the collector current of the discharge npn-transistor 17 of the first pulse expander 5 at the discharge timing capacitor 16 at an acceptable level for this transistor. A similar function is performed by the current-limiting resistor 36 of the second pulse expander 27. After the end of the input signal, the first pnp transistor 4 is turned off, its collector current assumes a value of I _f.o. close to zero. The discharge npn transistor 17 of the first pulse extender 5 is locked on the base with a negative bias voltage coming from the bias voltage bus 44 through the base resistor 15 of the first pulse extender 5. The output npn transistor 11 of the first extender 5 remains locked for some time after the discharge npn transistor 17 is turned off . This is explained by the fact that in the base circuit of the output npn transistor 11 there is a discharged time-setting capacitor 16 of the first pulse extender 5. This capacitor after turning off the discharge npn transistor 17 of the first pulse extender 5 starts charging from the positive supply voltage available on the bus of the positive supply voltage 42 through the time-setting resistor 13 of the first pulse expander 5, the current-limiting resistor 14 to the bus of the negative supply voltage 43. After a time interval τ _{zar 1} , _close the largest in terms of the intrinsic duration of the output pulse of the first pulse expander τ ₀₁ , the voltage based on the output npn transistor 11 of the first pulse expander 5 will exceed the cut-off voltage + E _{about the} output npn transistor 11, and the output npn transistor will turn on. The voltage at its collector will decrease to + U _kn . The capacitor 22 of the integrating RC link 18 is quickly discharged through the resistor 21 of the integrating RC link 18, which plays the role of a current-limiting element, and the output circuit (collector-emitter) of the saturated output npn transistor 11 of the first pulse expander 5. The voltage across the discharged capacitor 22 of the integrating RC of the link tending to the level of + U _kn becomes less than the voltage + U _о taken from the output of the second resistive divider 23, as a result of which the second pnp transistor 26 turns off. Turning off the second pnp transistor 26 entails turning off the discharge npn transistor 39 of the second pulse extender 27. After locking the discharge npn transistor 39 of the second pulse extender 27, the output npn transistor 33 of this extender remains off for some time, and this determines the possibility of providing time on state memory. The output npn transistor 33 of the second pulse extender remains turned off because there is a discharged time-setting capacitor 38 of the second pulse expander 27 in its base circuit. While this capacitor is charging, the voltage at the base of the output npn transistor 33 remains negative, and the output npn transistor 33 is locked up. The timing capacitor 38 of the second pulse extender 27 is charged through the circuit: the bus of the positive supply voltage 42 is the timing resistor 35 of the second pulse extender 27 is the current limiting resistor 36 of the second pulse extender 27 is the timing capacitor 38 of the second pulse extender 27 is the negative voltage bus 43. When in the process the voltage of the timing capacitor 38, the voltage at the base of the output npn transistor 33 of the second pulse expander 27 will exceed the input voltage cutoff voltage level acteristics + E _of this transistor, the transistor 33 turns on and the voltage at the output drops to a value of + U _book, i.e. to the level of logical zero. The on-state memory time is the sum of the time τ _charge 1 of the first pulse expander 5, the discharge time of the capacitor 22 of the integrating RC link 18 and the charge time τ charge _{2 of the} timing capacitor 38 of the second pulse expander 27. Since the charge time is τ charge _{2 of the} timing _pulse capacitor 38 the second pulse expander due to the appropriate choice of capacitor capacitance is set significantly larger than the remaining components, it can be considered that the on-state memory time is determined by the intrinsic duration the output pulse of the second pulse expander τ ₀₂ . The value of τ _{02 is} proportional to the value of the capacitance of the time-setting capacitor 38 of the second pulse expander.

When probing radar signals arrive in the form of packs of radio pulses with a packet duration of τ _p and a period of repetition of packets T _p, video pulses of a binary-quantized envelope of the packets with a video pulse close to τ _p and a period equal to T _p will be input to the input terminal 40 of the proposed device. The process of generating the output signal in this case is more complicated, because in addition to selection according to the total time of receiving input signals, selection is also carried out according to the period of the sequence of packets T _p .

We assume that T _p > T _p.gr. The boundary value of the repetition period of breeding packs is determined by the intrinsic pulse width τ _{0.1 of the} first pulse expander 5 and is proportional to the value of the capacitance of the time-setting capacitor 16 of this expander. At T> T _{pg, the} first pulse expander 5 generates pulse output signals. The output npn transistor 11 of the first pulse expander 5 is periodically locked for a time τ _0.1 = T _pg . During the time τ _{0.1, the} capacitor 22 of the integrating RC link 18 will be charged from the positive supply voltage acting on the bus 42 of the positive supply voltage through the collector resistor 12 of the first pulse expander 5 and the resistor 21 of the integrating RC link. The time constant of the charge circuit of the capacitor of the integrating RC link 18 is selected in such a way that during the time τ _{0.1 the} capacitor 22 of the integrating RC link 18 does not have time to charge up to the level + U _о specified by the second resistive divider 23. Therefore, the second pnp transistor 16 remains off, the second pulse expander 27 does not work, and there will be no response to the signal with a period T _p > T _pg . The signal at the output 40 of the device remains equal to logical zero.

After the end of the signal of the first pulse expander 5 with a duration of τ _{0.1, the} output npn transistor 11 of the first pulse expander 5 is again saturated, and the capacitor 22 of the integrating RC link 18 is quickly discharged through the resistor 21 of the integrating RC link, which has a small resistance value, and the output circuit (collector-emitter) saturated output npn transistor 11. Due to the very fast discharge of the capacitor 22 of the integrating RC link 18, no charge accumulation on this capacitor from pulse to pulse occurs, and to rihodu second input pulse at the initial conditions of the capacitor charging circuit 22 of the integrating RC-link will be the same as that of the first pulse exposure. Because of this, the second charge cycle, which again lasts τ _0.1 , will end in the same way as the first: the voltage across the capacitor 22 of the integrating RC link again does not have time to pass the threshold value + U _о . The voltage at the output 41 of the device will retain the level of logical zero, regardless of what was the total duration of exposure to the bursts of pulses with a repetition period T _p > T _pg .

Let us now consider the case when the period of the sequence of packs T _{p is} less than the boundary value of T _{p gr} . At T _p <T _{pg, the} output npn transistor 11 of the first pulse expander 5 will be locked during the entire time of arrival of such packs, i.e. during the time t _pr , consisting of several periods of succession of packs, and then during the time τ _0.1 after exposure to the last packet from the number received in time t _pr In this case, the capacitor 22 of the integrating RC link will be charged from a source of not a pulse but a constant voltage along the circuit: a bus of positive supply voltage 42 - a collector resistor 12 of the first pulse expander - resistor 21 of the integrating RC link - a common bus of the device. If t _pr > t _sp.gr. , then the voltage at the capacitor 22 of the integrating RC link will exceed the threshold level + U _{about the} voltage available at the output of the second resistive divider 23. In this case, the second pnp transistor 26 will turn on, which will lead to the operation of the second expander pulses 27 and the establishment of the level of the logical unit at its output 29 and the output of the device for generating the signal for switching on the jamming station 41. Thus, at T _p <T _p.gy and t _pr > t _spg at the output 41 of the proposed device, a signal of a logical unit is generated. If these conditions are not met, a logic zero signal will be stored at the output of the device.

The proposed device was tested experimentally. During the experiment, the following boundary values of the parameters were established: T _pgr = 0.17 sec; t _sp.gr. = 0.6 sec; τ _ram = 1.2 sec. Ten copies of the device were made according to the proposed scheme. In each of them, elements satisfying the technical conditions were installed without any selection or rejection. The experiment fully confirmed the feasibility of the device, its performance and the presence of the advantages noted above.

Claims (1)

 A signal generator for switching on the interference station, comprising a first resistive divider connected between the bus of the positive supply voltage and the common bus and made on series-connected first and second resistors, the connection point of which is the output of the first resistive divider, the first pulse expander made on the output npn transistor, connected by the base to the first output of the time-setting capacitor, the second output of which is connected to the negative supply voltage bus, the emitter - with a common a bus, a collector, which is the output of the first pulse expander, with the first output of the collector resistor, the second output of which is connected to the first output of the timing resistor and the bus of the positive supply voltage, and on the discharge npn transistor, the collector of which is connected to the first output of the current-limiting resistor, the emitter is connected to the bus of the negative supply voltage, and the base is connected to the first output of the base resistor integrating the RC link, the first and second conclusions of the resistor of which are the input of the integrating RC link connected to the output of the first pulse expander, and the output of the integrating RC link, the capacitor of which is connected between the common bus and the second output of the resistor of the integrating RC link, as well as the first pnp transistor, characterized in that the base of the discharge npn the transistor, which is the input of the first pulse extender, is connected to the collector of the first pnp transistor, the second output of the base resistor of the first pulse extender is connected to the negative bias voltage bus, the second terminal the main resistor is connected to the collector of the discharge npn transistor, the second output of the current-limiting resistor is connected to the base of the output npn transistor of the first pulse extender, the base of the first pnp transistor is connected to the output of the first resistive divider, and the emitter is the input of the shaper of the switching signal of the jamming station into which also a second pnp transistor, a second resistive divider, made and included similarly to the first resistive divider, and a second pulse expander, made similar to the first mu expander pulses, wherein the emitter of the second p-n-p-transistor coupled to the output of the integrating RC-link, base - with the output of the second resistive divider, the collector - to the input of the second pulse expander whose output is the output of interference signal switching station.

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